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EVALUATION OF THE REPRODUCTIVE AND DEVELOPMENTAL
TOXICITIES OF THE AQUEOUS EXTRACT OF
Labisia pumila var. alata IN FEMALE RATS
by
WAN EZUMI BINII MOHD PUAD @ MOHO FUAD
Thesis submitted in fulfilment of the requirements for the degree of
Doctor of Philosophy
October 2009
DECLARATION
I declare that the contents presented in this thesis are my own work, which was
done at School of Medical Sciences, Universiti Sains Malaysia unless stated
otherwise. The thesis has not been previously submitted for any other degree.
ACKNOWLEDGEMENTS
Dengan nama Allah Yang Maha Pengasih /agi Maha Penyayang
Alhamdulillah setinggi-tinggi kesyukuran dirafa'kan ke hadrat Allah SWT
kerana dengan limpah rahmat dan inayahnya telah memberikan saya kekuatan,
ketabahan dan keyakinan untuk menyiapkan kajian dan tesis ini. Sekalung
penghargaan dan jutaan terima kasih saya tujukan kepada kedua-dua penyelia
saya, Prof. Syed Mohsin Sahil Jamalullail dan Prof. Madya Dr. Siti Amrah
Sulaiman serta penyelia bersama, Dr. Mohd Suhaimi Abdul Wahab yang tidak
pernah jemu memberikan tunjuk ajar serta nasihat dan kritikan yang membina
di sepanjang saya menjalankan kajian ini. Ucapan penghargaan seterusnya
dikhaskan kepada Universiti Sains Malaysia yang menaja dan membiayai
pengajian saya melalui Skim Rancangan Latihan Kakitangan Akademik dan
terdahulu Skim Pasca Siswazah. Juga tidak ketinggalan, setinggi-tinggi
penghargaan kepada Geran Penyelidikan IRPA RM-8 tajaan Kementerian
Sains Teknologi dan Innovasi yang membiayai kajian ini.
Terima kasih yang tidak terhingga juga ditujukan kepada Prof. Madya Dr.
Syed Hatim Noor dan Dr. Kamarul Imran Musa yang telah memberikan
panduan di dalam analisis statistik, Prof. Madya Dr. Hasnan Jaafar di atas
tunjuk ajar dan pemeriksaan kajian histopatologi, Prof. Madya Dr. Farid Che
Ghazali di atas penyeliaan kajian elektron mikroskop serta Mr. S
Pannerchelvam dan Dr. Sarina Sulong di atas keprihatinan dan bantuan beliau
memer-iksa kandungan tesis ini. Seterusnya, segala bantuan akademik dan
teknikal yang dicurahkan oleh En. Lukmi Ismail, Puan Roslina Mat Zain, En.
II
Ruzman Mohd Nor, En. Harisal, ahli-ahli kumpulan Penyelidikan Perubatan
Herba dan Reproduktif Toksikologi, kakitangan Makmal Bioperubatan PPSK,
Unit Rumah Haiwan USMKK (LARU), Unit Fotografi PPSP, Jabatan Immunologi
PPSP, Unit Elektron Mikroskopi UKM dan semua pensyarah serta kakitangan
Jabatan Farmakologi PPSP amatlah dihargai.
Teristimewa saya ingin merakamkan terima kasih yang tidak terhingga
kepada suami tercinta, Mohd Anizan Bakhtiar b. Abdullah yang banyak
menghulurkan bantuan teknikal dan tunjuk ajar kepada saya di dalam
menjalankan kerja-kerja penyelidikan serta sokongan moral yang tidak berbelah
bahagi di sepanjang saya mengharungi pengajian dan kehidupan di alam
kampus ini. Buat anak sulung tersayang Irsyad Rizqy, keletah dan
kemanjaannya amat menghiburkan dan menguatkan semangat saya saban
hari. Kepada kedua ibu bapa tersayang, ayahanda Mohd Fuad b. Abdul
Rahman dan bonda Wan Kamariah bt. Wan Daud, adinda-adinda serta saudara
mara yang dikasihi, segala doa, pengorbanan dan sokongan ikhlas kalian akan
dikenang sehingga ke akhir hayat. Buat rakan-rakan seperjuangan di PPSP,
PPSK dan PPSG terima kasih diucapkan di atas persahabatan yang dihulurkan
yang memberikan saya kekuatan di dalam mengharungi kehidupan bergelar
pelajar ijazah lanjutan ini.
Akhir kata, semoga kajian dan tesisini dapat memberi manfaat kepada
semua. Mudah-mudahan segala penat lelah dan pengorbanan kita mendapat
keberkatan daripada Allah SWT.
iii
TABLE OF CONTENTS
ACKNOWLEDGEMENTS
TABLE OF CONTENTS
LIST OF TABLES
LIST OF FIGURES
LIST OF PLATES
LIST OF SYMBOLS AND ABBREVIATION
ABSTRAK
ABSTRACT
CHAPTER ONE: INTRODUCTION
1.1 Preface
1.2 Reproductive and developmental toxicology
1.3 Herbal medicine
1.3.1 Safety issue of herbal medicine
1.3.2 Labisia pumila (Blume) Fern.-Vill
1.4 Scope of the study
1.4.1 Test procedures and guidelines used
1.5 Objectives
1.5.1 General objectives
1.5.2 Specific objectives
1.6 Importance of the study
CHAPTER TWO: LITERATURE REVIEW
2.1 Medicinal plants in Malaysia
Page
ii
iv
XI
xiii
xiv
xvi
xix
xxi
1
1
3
5
8
11
14
16
17
17
17
19
21
21
2.2 Research and development of herbal medicine in Malaysia 25
2.3 Detailed information on Labisia pumila 30
2.3.1 General description
2.3.2 Botanical characteristic
iv
30
30
2.3.3 Traditional and commercial herbal preparation 33
2.3.4 Chemical constituents 34
2.3.5 Biological activities 35
2.3.6 Ethnobotanical research 36
2.3.7 Toxicity and side effects 37
2.4 Evaluation and regulation of herbal medicine products in 40 Malaysia
2.4.1 Preclinical safety and toxicity assessment of new 41 herbal drugs
2.4.2 Clinical trials 42
2.5 Regulatory guidelines for reproductive and developmental 43 toxicology
2.5.1 The WHO General Guidelines for Methodologies on 44 Research and Evaluation of Traditional Medicine
2.5.2 The OECD Guidelines for the Testing of Chemicals 45
2.5.3 The U.S FDA Redbook 2000: Toxicological Principles 47 for the Safety Assessment of Food Ingredients
2.5.4 The ICH Guidelines for Detection of Toxicity to 49 Reproduction for Medicinal Products
2.6 Use of animals in reproductive and developmental 52 toxicology research
2.6.1 I ntrod uction 52
2.6.2 Biological features of reproductive system of female 55 rats
CHAPTER THREE: MATERIALS AND METHODS 60
3.1 Preliminary Study on the Effects of Aqueous Extract of LPA 60 on Teratogenicity in Rats
3.1.1 Objectives
3.1.2 Research and ethical committee approval
3.1.3 Chemicals and experimental equipments
3.1.4 Plant materials
3.1.4.1 Plant extraction
3.1.4.2 Dosage preparation
3.1.4.2.1 Dosage calculation
v
60
60
60
61
61
64
65
3.1.5 Animals 67
3.1.5.1 Housing and identification 67
3.1.6 Experimental protocol 68
3.1.6.1 Vaginal smear and determination of oestrous 68 cycle
3.1.6.2 Mating procedures and determination of 69 pregnancy
3.1.6.3 Dose administration 69
3.1.6.4 General observation and behavioural 70 changes of animals
3.1.6.5 Termination of animals 70
3.1.6.6 Gross examination of animals 71
3.1.6.7 Parameters of study 73
3.1.7 Statistical analysis 75
3.2 Main Study I: Evaluation of the Teratogenicity of Biolabisia® 79 in Rats
3.2.1 Objectives 79
3.2.2 Chemicals and experimental equipments 79
3.2.3 Research and ethical committee approval 79
3.2.4 Plant materials 79
3.2.4.1 Plant extraction 80
3.2.4.2 Dosage preparation 81
3.2.4.2.1 Dosage calculation 81
3.2.5 Animals 82
3.2.6 Experimental protocol 82
3.2.6.1 Histopathology of reproductive organs 83
3.2.6.1.1 Fixation 83
3.2.6.1.2 Processing of tissue samples 84
3.2.6.1.3 Paraffin wax embedding 84
3.2.6.1.4 Section cutting 85
3.2.6.1.5 Staining 86
3.2.6.1.6 Slide evaluation 87
3.2.6.2 Parameters of study 88
3.2.7 Statts-tical analysis 91
vi
3.3 Main Study II: Evaluation of the Female Reproductive 97 Toxicity of Biolabisia® in Rats
3.3.1 Objectives 97
3.3.2 Chemicals and experimental equipments
3.3.3 Plant materials
3.3.4 Animals
3.3.5 Experimental protocol
3.3.5.1 Histopathology of reproductive organs
3.3.5.2 Parameters of study
3.3.6 Statistical analysis
97
97
97
98
100
101
104
3.4 Main Study III: Evaluation on the Effects of Biolabisia® on 105 Fertility and Implantation in Rats
3.4.1 Objectives 105
3.4.2 Chemicals and experimental equipments
3.4.3 Plant materials
3.4.4 Animals
3.4.5 Experimental protocol
3.4.5.1 Histopathology of reproductive organs
3.4.5.2 Parameters of study
3.4.6 Statistical analysis
105
105
105
106
107
109
112
3.5 Main Study IV: Evaluation of the Female Toxicity of 113 Biolabisia® in Rats
3.5.1 Objectives 113
3.5.2 Chemicals and experimental equipments 113
3.5.3 Plant materials 113
3.5.4 Animals 113
3.5.5 Experimental protocol 114
3.5.5.1 Blood collection for hormonal analysis 115
3.5.5.2 ELISA hormonal assay 115
3.5.5.2.1 General principle of ELISA assay 115
3.5.5.2.2 General procedure of ELISA 117 assay
3.5.5.2.3 ELISA assay reproducibility 119
vii
3.5.5.3 Histopathology of reproductive organs
3.5.5.4 Parameters of study
3.5.6 Statistical analysis
CHAPTER FOUR : RESULTS
120
121
124
127
4.1 Preliminary Study on the Effects of Aqueous Extract of LPA 127 on Teratogenicity in Rats
4.1.1 Authentication of plant materials and aqueous 127 extraction of LPA
4.1.2 General observation of health status of female rats 130
4.1.3 Gross examination at autopsy 130
4.1.4 Pregnancy outcomes 130
4.1.5 Foetal observation 131
4.2 Main Study I: Evaluation of the Teratogenicity of Biolabisia® 133 in Rats
4.2.1 Health status and fates of female rats
4.2.2 Gross examination at autopsy
4.2.3 Maternal body weight (MBW), weight gain and percentage changes in MBW
4.2.4 Corrected maternal body weight (CMBW)
133
133
135
135
4.2.5 Number of corpora lutea and implantation sites per 138 litter
4.2.6 Post-implantation death and resorption of conceptus 138
4.2.7 Organ weights 138
4.2.8 Histopathological findings 142
4.2.9 Number of live foetuses per litter 145
4.2.10 Sex distribution and foetal weight (male and female) 145
4.2.11 External malformations 147
4.3 Main Study II: Evaluation of the Female Reproductive 149 Toxicity of Biolabisia® in Rats
4.3.1 Health status and fates of female rats 149
4.3.2 Gross examination at autopsy
4.3.3 Maternal body weight (MBW), weight gain and percentage changes in MBW
4.3.4 Oestrous cyclicity
4.3.5 Mating index and duration of successful mating
viii
149
151
154
154
4.3.6 Pregnancy evaluations
4.3.7 Implantation sites and post-implantation death
4.3.8 Organ weights
4.3.9 Gross and histopathological findings
4.3.10 Body weight and growth rates of pups
4.3.11 Pup evaluations
164
164
164
166
169
169
4.4 Main Study III: Evaluation on the Effects of Biolabisia® on 172 Fertility and Implantation in Rats
4.4.1 General signs of toxicity of female rats
4.4.2 Gross examination at autopsy
172
172
4.4.3 Maternal body weight (MBW), weight gain and 172 percentage change in MBW
4.4.4 Corrected maternal body weight (CMBW) 173
4.4.5 Oestrous cyclicity 176
4.4.6 Organ weights 181
4.4.7 Histopathological findings 181
4.4.8 Number of corpora lutea, number of implantation 185 sites and pre-implantation loss
4.4.9 Post-implantation death and resorption of conceptus 185
4.4.10 Number of live and dead foetuses per litter 189
4.4.11 Foetal body weight and external malformations 189
4.5 Main Study IV: Evaluation of the Female Toxicity of 190 Biolabisia® in Rats
4.5.1 General health and signs of toxicity 190
4.5.2 Gross examination at autopsy 190
4.5.3 Body weight, weight gain and percentage changes 190 in body weight
4.5.4 Oestrous cyclicity
4.5.5 Organ weights
4.5.6 Gross and histopathological findings
4.5.7 Analysis of hormones
ix
193
198
198
206
CHAPTER FIVE: DISCUSSION 210
5.1 Preliminary Study on the Effects of Aqueous Extract of LPA 213 on Teratogenicity in Rats
5.2 Main Study I: Evaluation of the Teratogenicity of Biolabisia® 215 in Rats
5.3 Main Study II: Evaluation of the Female Reproductive 221 Toxicity of Biolabisia® in Rats
5.4 Main Study III: Evaluation on the Effects of Biolabisia® on 228 Fertility and Implantation in Rats
5.5 Main Study IV: Evaluation of the Female Toxicity of 236 Biolabisia® in Rats
5.6 Overall discussion 247
CHAPTER SIX: CONCLUSION AND RECOMMENDATIONS
FOR FUTURE RESEARCH
6.1 Conclusion
6.2 Recommendations for future research
BIBLIOGRAPHY
APPENDICES
Appendix 1 : Research and ethical committee approval
Appendix 2 : Procedure of thin layer chromatography (TLC)
Appendix 3 : General observation and behavioural changes chart
Appendix 4 : Litter collection sheet
Appendix 5 : Lists of publications and presentations
Appendix 6 : Published papers
Appendix 7 : Abstracts of scientific conferences and seminars
x
269
269
272
275
Table
2.1
3.1
3.2
3.3
3.4
3.5
3.6
3.7
3.8
4.1
4.2
4.3
4.4
4.5
4.6
4.7
4.8
LIST OF TABLES
Comparison of guidelines and study designs where similar observations are made
List of chemicals and laboratory equipments used in the preliminary study
Qualitative parameters incorporated in histopathological examinations of ovary
List of chemicals and laboratory equipments used in the Teratogenic study
Qualitative parameters incorporated in histopathological examinations of uterus
Qualitative and quantitative parameters incorporated In histopathological examinations of ovary and vagina
Type of reagents and its respective volume for ELISA assay
Qualitative and quantitative parameters incorporated in histopathological examinations of uterus
List of chemicals and laboratory equipments used in the Female toxicity study
Amount of aqueous extract of LPA obtained from 24 g of raw materials each in three different extractions
Data of the preliminary study
Maternal parameters of rats treated with Biolabisia® at 0, 2, 20,200,400 and 1000 mg/kg/day from 06 through 016 pc
Reproductive and foetal parameters of rats administered with various doses of Biolabisia® from 06 through 016 pc
Maternal parameters of rats treated with Biolabisia® at premating, mating, gestation and lactation periods of seven days
Oestrous cycle phases of rats during pre-treatment and while on treatment with Biolabisia®
Pregnancy and reproductive parameters of rats treated with Biolabisia® at pre-mating, mating, gestation and lactation periods of seven days
Foetal parameters of rats treated with Biolabisia® at premating, mating, gestation and lactation periods of seven days
xi
Page
51
76
87
93
100
111
118
120
125
129
132
137
139
153
158
165
170
4.9 Maternal and reproductive data of rats treated with 175 Biolabisia® at pre-mating, mating and gestation periods lasting 15 days.
4.10 Oestrous cycle phases of rats treated with Biolabisia® during 177 pre-mating period for duration of two weeks.
4.11 Reproductive organ weights and quantitative 182 histopathological findings of females administered orally with Biolabisia® at pre-mating, mating and gestation periods of up to 015 pc.
4.12 Reproductive and foetal data of animals treated orally with 188 Biolabisia® at pre-mating, mating and gestation periods of up to 015 pc.
4.13 Summary of observations on female rats after receiving 192 daily administration of Biolabisia® for three weeks
4.14 Oestrous cycle phases of rats treated with Biolabisia® for 194 duration of three weeks
4.15 Reproductive organ weights and quantitative 201 histopathological data of females after receiving daily treatment of Biolabisia® for three weeks
4.16 Serum hormone levels of rats during diestrus phase 207 following three weeks Biolabisia® treatment
xii
LIST OF FIGURES
Figure Page
1.1 Flowchart of the study indicating important research activities 18
3.1 Flowchart of LPA extraction in the preliminary study 63
3.2 Experimental design of the preliminary study 74
3.3 Experimental design of the Teratogenic study 90
3.4 Experimental design of the Reproductive toxicity study 103
3.5 Experimental design of the study 108
3.6 Experimental design of the Female toxicity study 123
4.1 Graph of the maternal body weights (MBW) in the 136 Teratogenic study
4.2 Graph of the maternal body weights (MBW) of treated and 152 control groups of animals in the Reproductive toxicity study
4.3 Graph of the maternal body weights (MBW) of treated and 174 control groups of animals in the Fertility study
4.4 Graph showing the body weights of treated and control 191 groups of animals in the Female toxicity study
4.5 Effects of three weeks Biolabisia® treatment on the serum 17- 208 /3 oestradiol and progesterone levels of female rats in the Female toxicity study
4.6 Bar chart presenting the free testosterone levels of female 209 rats in the Female toxicity study
xiii
Plate
2.1
2.1 (a)
2.1 (b)
2.1 (c)
2.1 (d)
2.1 (e)
4.1
4.2
4.3
4.4
4.5
4.6
4.7
4.8
4.9
4.10
4.11
4.12
LIST OF PLATES
Labisia pumila (Blume) Fern.-Vill plant
L. pumila flower
L. pumila fruit
L. pumila var. alata
L. pumila var. pumila
L. pumila var. lanceo/ata
TLC chromatogram of ethanol extracts of LPA roots and leaves
Macroscopic features of aqueous extract of LPA
Photograph of normal pregnant dam from the control group during autopsy in the Teratogenic study
Photograph of normal gravid uterus containing foetuses at 021 pc from the 1000 mg/kg/day dose group in the Teratogenic study
Photograph of cut-opened gravid uterus showing normal foetuses in the Teratogenic study
Light photomicrographs of the ovary on 021 pc in the Teratogenic study
Photograph of normal life foetuses with placenta attached from the Biolabisia® 2 mg/kg/day dose group in the Teratogenic study
Photograph of a normal, still-breathing rat foetus without any external malformation from the control group in the Teratogenic study
Photograph of visible normal implantation sites (scars) of the seventh day post partum uterus in the Reproductive Toxicity study
A metestrus smears consisting of the same proportion among cornified, leukocytes and nucleated epithelial cells
A diestrus smears primarily consisting of a predominance of leukocytes
A proestrus smears consisting of abundant nucleated noncornified epithelial cells mostly arranged in "grape-like clusters"
xiv
Page
32
32
32
32
32
32
128
129
134
140
141
143
146
148
150
155
155
156
4.13 An estrus smears indicating the presence of large 156 anucleated cornified cells in the vaginal smear
4.14 A sperm positive smears 157
4.15 Photomicrographs of cross sectional uteri stained with 167 H & E in the Reproductive toxicity study
4.16 Photograph showing the specific external organs of pups 171 used to make physical examinations to locate for any congenital malformation in the Reproductive toxicity study
4.17 Photomicrographs showing the ovary on 016 pc in the 183 Fertility study
4.18 Photomicrographs showing a cross section of the vagina 184 on 016 pc in the Fertility study
4.19 Photograph of normal gravid uterus on 016 pc with 186 foetuses enclosed in amniotic sac from the 200 mg/kg/day dose group in the Fertility study
4.20 Photograph showing gravid uterus of rat with a resorption 187 from the 20 mg/kg/day dose group in the Fertility study
4.21 Histopathology of ovaries stained with H & E in the Female 202 Toxicity study
4.21 (e) Histopathology of ovary showing several cystic follicles 203 (CF) in the Female toxicity study
4.22 Photomicrographs of cross sectional uteri in the Female 204 toxicity study
4.23 Histopathology of vagina in the Female toxicity study 205
xv
ANOVA
CFSAN
CMBW
o DCA
Ddel
Dkill
OW
E
EU
FBW
FRIM
FSH
F. tes.
g
GMP
GnRH
GUW
H&E
HKL
HUKM
HUSM
ICH
IMR
IQR
KF
kg
LH
LPA
LD50
LIST OF SYMBOLS AND ABBREVIATIONS
Analysis of variance
Center for Food Safety and Applied Nutrition
Corrected maternal body weight
Degree of Celcius
Diestrus
Drug Control Authority
Day upon delivery
Day upon sacrifice
Distilled water
Estrus
European Union
Female body weight
Forest Research Institute of Malaysia
Follicle stimulating hormone
Free testosterone
gram
Good Manufacturing Practice
Gonadotropin-releasing hormone
Gravid uterine weight
Haematoxylin and eosin
Kuala Lumpur Hospital
Hospital Universiti Kebangsaan Malaysia
Hospital Universiti Sains Malaysia
International Conference on Harmonization
Institute for Medical Research
Interquartile range
Kacip Fatimah
Kilogram
Luteinizing hormone
Labisia pumi/a var. a/ata
Median lethal dose
xvi
LPL
LPP
M
MARDI
MBW
mg
ml
MOH
n
NCTR
NOAEL
NPCB
NRDHM
OECD
P
pc
Prog.
SEM
SO
T/CM
TLC
UH
UK
UKM
UM
UMS
UTM
US
USA
USEPA
USFDA
Labisia pumi/a var. lanceo/ata
Labisia pumi/a var. pumi/a
Metestrus
Malaysian Agricultural Research and Development Institute
Maternal body weight
milligram
mi"ilitre
Ministry of Health
Sample size of animal
National Center for Toxicological Research
No observable adverse effect level
National Pharmaceutical Control Bureau
National Committee for Research and Development in Herbal Medicines
Organization for Economic and Cooperation and Development
Proestrus
Post-coitus
Progesterone
Standard error of mean
Sprague Dawley
Traditional and complimentary medicine
Thin layer chromatography
Universiti Hospital, Universiti Malaya
United kingdom
Universiti Kebangsaan Malaysia
Universiti Malaya
Universiti Malaysia Sabah
Universiti Teknologi Malaysia
United States
United State of America
United States Environmental Protection Agency
United States Food and Drug Administration
xvii
USM
WHO
11 ~-HSD1
17 -13 oestradiol
Universiti Sains Malaysia
World Health Organization
11 Beta Hydroxysteroid Dehydrogenase type 1
17 -Beta oestrad iol
xviii
KAJIAN KETOKSIKAN REPRODUKTIF DAN PERTUMBUHAN EKSTRAK
AIR Labisia pumila var. a/ata PADA TIKUS BETINA
ABSTRAK
Labisia pumi/a var. a/ata (LPA) atau Kacip Fatimah disenaraikan sebagai
salah satu spesis utama oleh kerajaan Malaysia untuk dijalankan kajian saintifik
pelbagai disiplin ke arah pembangunan ubatan herba tempatan berasaskan
bukti saintifik. Kajian yang dihuraikan di dalam tesis ini adalah sebahagian
daripada kajian pra klinikal ke atas LPA untuk menilai profil keselamatannya.
Tujuan kajian ini adalah untuk menentukan potensi kesan sediaan komersial
ekstrak air LPA ke atas ketoksikan reproduktif dan pertumbuhan pada tikus
betina Sprague Dawley. Kajian permulaan dijalankan dengan menggunakan
ekstrak air tidak terpiawai LPA pada dos 2, 20, 200 dan 400 mg/kg/hari.
Sediaan komersial ekstrak air terpiawai LPA, didaftarkan sebagai Biolabisia®
pad a dos 2, 20, 200, 400, 1000 mg/kg/hari atau air suling (kawalan) diberikan
kepada tikus secara gavaging dalam kajian utama. Kajian Teratogenik
dijalankan dengan memberikan rawatan Biolabisia® kepada tikus hamil semasa
peringkat organogenesis. Rawatan ke atas tikus diberi sejak sebelum tempoh
mengawan sehingga hari ke-7 waktu laktasi dalam kajian Ketoksikan
reproduktif dan sebelum mengawan sehingga hari ke-15 kehamilan bagi kajian
Kesuburan. Tikus dara diberikan rawatan dengan Biolabisia® selama tiga
minggu dalam kajian ketoksikan am. Beberapa parameter reproduktif dan
pertumbuhan dinilai di sepanjang tempoh kajian. Semua data numerikal
dianalisa menggunakan SPSS versi 12.0.1. Keputusan diperolehi menunjukkan
xix
pemberian semua tahap dos Biolabisia® tidak menyebabkan kematian atau
tanda-tanda ketoksikan yang ketara pada keadaan fizikal dan perlakuan
keseluruhan tikus yang dikaji. Berat badan tikus betina menunjukkan corak
perubahan yang sam a tetapi tiada keputusan yang signifikan di dalam semua
eksperimen kecuali bagi penurunan signifikan berat badan dan berat badan
sebenar ibu di dalam kajian Kesuburan. Rawatan dengan Biolabisia® tidak
menyebabkan kesan teratogenik ke atas tikus di mana tiada fetus yang
mempamerkan kecacatan kongenital luaran. Jumlah bilangan korpora lutea,
bilangan tapak implantasi, peratus kehilangan embrio sebelum implantasi,
peratus kematian embrio selepas implantasi, bilangan resorpsi fetus, bilangan
fetus hidup, be rat badan fetus dan nisbah jantina fetus adalah setanding di
kalangan semua kumpulan rawatan. Tempoh kitaran estrus dan berat organ
reproduktif tidak terjejas oleh Biolabisia® secara statistik. Walaubagaimanapun,
peningkatan bilangan tikus dengan kitaran estrus tidak teratur, kemunculan sis
folikel ovari dan corak peningkatan aras hormon progesteron and testosterone
bebas bagi kumpulan yang menerima dos Biolabisia® 1000 mg/kg/hari
mencetuskan kebimbangan. Dengan mengambil kira semua data terkumpul,
penemuan kajian ini mencadangkan bahawa rawatan oral Biolabisia® sehingga
ke dos 1000 mg/kg/hari ke atas tikus betina tidak menunjukkan kesan
ketoksikan yang signifikan. Walaubagaimanapun, berat badan dan kitaran
estrus tikus berkemungkinan terjejas jika rawatan dengan Biolabisia® pad a dos
tinggi diberikan untuk jangkamasa panjang. Penyelidikan berterusan
menggunakan spes is haiwan bukan roden perlu dijalankan untuk
melengkapkan profil keselamatan herba ini.
xx
EVALUATION OF THE REPRODUCTIVE AND DEVELOPMENTAL
TOXICITIES OF THE AQUEOUS EXTRACT OF
Labisia pumila var. a/ata IN FEMALE RATS
ABSTRACT
Labisia pumi/a var, a/ala (LPA) or Kacip Fatimah has been listed by the
government of Malaysia as one of the priority species for a multi-disciplinary
scientific study towards the development of scientific, evidence-based herbal
medicine. The present study described in this thesis is part of the preclinical
assessment of LPA to evaluate its safety profile. The aims of this study were to
evaluate the potential effects of aqueous extract of LPA on reproductive and
developmental toxicities in Sprague Dawley rats. A preliminary study was
conducted using unstandardised extract of LPA at 2, 20, 200 and 400
mg/kg/day. Commercially prepared standard aqueous extract of LPA, registered
as Biolabisia® at the doses of 2,20, 200,400, 1000 mg/kg/day or distilled water
(control) were administered by gavaging to animals during the main studies.
The Teratogenic study was conducted by treating pregnant animals with
Biolabisia® during the period of organogenesis. Treatments of animals began
from the time prior to mating until lactational periods of seven days in the
Reproductive toxicity study and from before mating up to day 15 of pregnancy in
the Fertility study. Virgin rats were treated with Biolabisia® for duration of three
weeks in the Female toxicity study. A substantial number of reproductive and
developmental parameters were assessed throughout this study. All numerical
data were analysed using SPSS version 12.0.1. Results obtained indicated that
xxi
the administration of Biolabisia® at all dose levels did not cause mortality nor
show noticeably any treatment-related signs of toxicity on the physical
appearance and behaviour of all the rats studied. There was a consistent trend
with body weight changes of females in all the experiments performed but they
showed no significant differences except for the significant reduction in the
actual and corrected maternal body weights of Biolabisia® -treated animals in
the Fertility study. Treatment with Biolabisia® did not result in teratogenicity in
rats since no foetus exhibited external congenital malformations. The total
number of corpora lutea, number of implantation sites, percentages of pre
implantation loss and post-implantation death, number of resorptions, number of
live foetuses, foetal body weight and foetal sex ratio were comparable among
all experimental groups. The length of oestrous cycles and reproductive organs
weights of rats were statistically unaffected by Biolabisia®. However, high
number of animals with irregular cycles, presence of ovarian follicular cysts and
a trend of increased serum progesterone and free testosterone levels that were
observed in the Biolabisia® 1000 mg/kg/day dose group do raised some
concern. Taking all the cumulative data together, the current findings suggest
that oral treatment of Biolabisia® of up to 1000 mg/kg/day in female rats is not
associated with significant deleterious effects. However, the body weight and
oestrous cycle of the females may be affected if higher doses of Biolabisia® are
administered for a longer duration. Studies involving non-rodent animal species
need to be performed to complete the safety profile of this herb.
xxii
CHAPTER ONE
INTRODUCTION
1.1 Preface
During the 21 5t century, there has been an elevated level of hazardous
risk due to xenobiotics and toxic substances towards the reproductive function
of the human (Osamu, 2005). These groups of substances which include
synthetics, naturally occurring chemicals, natural products, food additives,
drugs, heavy metals, environmental pollutants, natural toxin and so forth have
been included in the list of possible hazards (Sharara et al., 1998). Some of the
substances are recognised (Hutz et al., 2006; Llanos and Ronco, 2009) and
some are suspected (Sharara et al., 1998) as reproductive toxicants. Yet, there
are still marketed products that use materials or chemicals, which have not
been analyzed for its reproductive toxicity.
In many instances, women are believed to be more vulnerable and at a
higher risk than men in experiencing negative responses while being assessed
with the reproductive effects of some of the aforementioned agents (Hoyer,
2001; Butter, 2006; Vahter et al., 2007). Episodic exposure to high levels of
some of these agents is responsible for the acute and chronic female
reproductive and developmental health problems. Disorders of reproduction
reported in females include infertility, menstrual disorders, reduction in libido,
pregnancy complications, adverse outcomes of pregnancy, spontaneous
abortion, low birth weight, heritable defects, premature reproductive
1
senescence, lactation disorders, various genetic diseases, and cancers (Daston
et al., 1997; Drozdowsky and Whittaker, 1999; Hutz et aI., 2006).
The prevailing risks from the above-mentioned inputs towards female
reproductive health have caused much public concern and regarded as a
relatively recent medical challenges raising considerable attention from
scientific communities and legislators (Daston et al., 1997; Kimmel and Makris,
2001). Stemming from conventional toxicology, this area of interest has evolved
and ramified into a field known as female reproductive and developmental
toxicology (Neubert et al., 1999a; Christian, 2001 c; Collins, 2006).
In Malaysia, the field of reproductive toxicology is comparatively new as
an area of research. To date, Malaysia is not a member in any of the
international toxicological organization. Nevertheless, Malaysia through its
Ministry of Health (MOH) has adapted various existing international guidance
and has come out with its own regulation for conducting toxicological testing of
materials (Ministry of Health Malaysia, 2003a). Researchers in this country are
now ushering the community to take steps towards exploring this field upon
realizing its enormous importance. These actions are genuinely taken in an
attempt to improve the general health of the nation. Reproductive toxicology is
currently experiencing a surge significance as there is a thrust in this area by
the Malaysian government to encourage the production of high quality herbal
products and nutraceuticals derived from local bioresources. The toxicological
testings required in the development of these products will help to reduce public
anxiety over the possible deleterious effects associated with herbal use.
2
1.2 Reproductive and developmental toxicology
Toxicology is the study of poisons, their adverse effects on biological
systems and methods of treatment for conditions they produce (Friis, 2006).
The challenging science of toxicology has been in existence for many centuries.
It has evolved from an expression of thoughts concerning poisons, victims and
plants or chemicals as sources of ills to the current scientific discipline that it is.
This field continues to establish and expand its principles into a range of sub
specializations, for instance, reproductive and development toxicology, food and
chemical toxicology, occupational medicine and industrial toxicology, forensic
toxicology and so forth. All share one main goal that is to provide valuable
information in the pursuit of ideals to protect people from harmful effects of
hazardous agents (Borzelleca, 2001). Among the wide range of potential health
risks, a prominent concern is that the agents may interfere with the functions of
the reproductive system vis-a-vis reproductive and developmental toxicology.
Reproductive and developmental toxicology investigate the effects of
drug and other xenobiotics, which collectively show potential to impair human
reproductive health. The consequences of even minor impairment during the
reproductive process and / or during the development of the growing foetus can
result in devastating outcomes to the organism (Miller et al., 2004). The
complexity of component within the reproductive unit comprising the dam, sire
and the progenies has driven the field of reproductive toxicology to be one of
the vital scientific specialization recognised globally (Hoyer, 2001). According to
Hayes (2001 a), reproductive toxicology is concerned with the causes,
mechanism and sequelae of adverse effects of substances on the reproductive
3
process. The adverse effects may include alterations to the sexual organs and
their functions, related endocrine regulation or pregnancy outcomes. They can
be manifested as aberrations or modifications on sexual maturation, gamete
production and transport, oestrous cycle, sexual behaviour, fertility, gestation,
parturition, lactation, pregnancy outcomes and reproductive senescence
(Christian, 2001 c). The field is separated into areas related to male and female
fertility, and developmental toxicology (sometimes referred to as teratogenicity).
Developmental toxicology is the study of the causes, mechanisms and
sequelae of perturbed developmental events in species of animals that undergo
ontogenesis. The affected endpoints include death, delayed / retarded
development, dysmorphology and functional impairment (Hayes, 2001b). Based
on these definitions, developmental toxicology is considered synonymous with
"teratology". Special emphasis is put on the developing conceptus, which
include the development and function of that conceptus throughout its entire
lifespan (Christian, 2001c). This field can be further narrowed down into
prenatal and postnatal toxicology (Hayes, 2001c).
Presently toxicological evaluation and regulations of chemicals referred
earlier were developed and reviewed as a consequence of three human
tragedies that resulted from in utero exposure to drugs; (i) thalidomide -
congenital malformations, (ii) Minimata disease - behavioural/functional
alterations and (iii) diethylstilbestrol (DES) - cancer (Christian, 2001 c). Before
the "Thalidomide disaster" (1959-1962), no routine toxicological evaluation of
4
chemicals and drugs on reproduction and development was carried out
(Neubert et al., 1999a).
Only in mid-1960s, the systematic preclinical studies of the possible
adverse effects on reproduction and development necessitated the need for the
registration of new pharmaceutical products and certain types of
environmentally occurring chemicals, such as pesticides (Neubert et al., 1999a).
However, the regulatory research and testing guidelines needed to be reviewed
and improved especially after the first and second outbreak of Minimata disease
in 1956 and 1965. This occurrence has increased concerns regarding adverse
effects of highly toxic chemicals that can cause severe health problems and
death to people and animals. Furthermore, cancer that resulted from exposure
to DES in early 1970s has once again raised additional attention concerning
deleterious effects that were not noticeable until after puberty. Thus, a broad
range of endpoints in guidelines was required to evaluate various aspects of
potential reproductive toxicity (Christian, 2001c).
1.3 Herbal medicine
Herbal medicine (phytomedicine / botanical medicine) constitutes one of
the leading complementary therapies in this century. It is a common component
in Ayurveda, pharmacotherapy, homeopathy, naturopathy and so forth. It refers
to the use of finished, labelled medicinal products that contain active ingredients
of aerial or underground parts of plants, or other plant material, or combinations,
whether in the crude form or as plant preparations for the purposes of
maintaining and the healing of various health conditions. Herbal medicines may
5
contain excipients in addition to the active ingredients. Medicines containing
plant material combined with chemically defined substances are however, not
considered to be herbal medicines (World Health Organization, 1996). The
utilisation of herbs as medicine started since time immemorial. Its contributions
in maintaining human health is very impressive and well recognised globally.
The World Health Organisation (WHO) estimated that 80% of the world
population rely on it for their health care needs (Shrivastava et a/., 2007).
In recent years, we are witnessing enormous public interests in the use
of herbal remedies despite the advancement of modern medicine. The
popularity of herbs is experiencing a renewed resurgence with new approaches
and use. According to WHO, the herbal usage throughout the world exceeds
that of the conventional drugs by two to three times (Pal and Shukla, 2003). The
numerous varieties of herbal products in the market are testimony of the current
upward trend in its use. They have been widely consumed as alternative
medicines in conjunction with conventional synthetic drugs to treat a variety of
medical conditions and reverse the progression of health disorders (Kamboj,
2000; Erah, 2002) including premature aging, obesity, body weakness, sexual
dysfunction, menopause, women's problem, chronic diseases et cetera.
For various reasons, people often turn to herbal medicines when their
long-lasting illness could not be cured by conventional medicine, also when
these products can satisfy their needs and show no untoward side effects (Pal
and Shukla, 2003). Herbal remedies are not only used in the prevention and
treatment of diseases but are also utilized as alternative approaches to enhance
6
overall well being while they are still in a good health. The healing power of
herbs is thought to sooth the soul and help people feel better and live longer
due to the naturally derived substances present in them (Kamboj, 2000; Abas,
2001; Seeft, 2009). Moreover, the lower costs and the ease of self-medication
with herbal products when compared to synthetic medicine give people a
perceived ability to personally control their health (Pal and Shukla, 2003). Apart
from the above, the holistic practices that is associated with herbal medicine like
prayers (doa), incantation Oampi), abstinence (pantang) and other practices
make the process of rehabilitation and health promotion alive and real (Zakaria
and Mohd, 1994; Haliza, 2000). Additionally, the believe that herbal medicines
are natural products and are therefore safe also contribute to their popularity
(Abas, 2001; Niggemann and Gruber, 2003). Although, the fact remains that the
safety of plant materials can only be established upon proper scientific studies.
In Malaysia, the government realizes and draws attention to the huge
contribution of herbal medicines both in the traditional and complementary
medical systems. The government has in stages actively providing the direction
for the country in relation to the implementation of strategies, formulation of
action plans and programmes, research and development related to herbs. All
efforts are now focused towards establishing herbal industry at international
level. This becomes one of the main agenda in the eighth Malaysian
Development Plan (Ministry of Agriculture Malaysia, 2000; Ministry of Health
Malaysia, 2000). These are expected to help spearhead, improve and sustain
the herbal industry as an important economic contributor to the nation's coffers.
7
1.3.1 Safety issue of herbal medicine
Safety is one of the consumer's basic rights, It is defined as the right to
be protected against the marketing of goods or provisions of services that are
hazardous to health and life (Mohan, 2001). Although there has been a huge
escalation in the use of herbs in our country and the world, the scientific input to
backup their usage are still lacking. The quality, safety and efficacy of these
products remain the main issues of relevance (Erah, 2002; Barnes, 2003). The
concern for toxic side effects, their efficacy and limitations must be given
serious attention and should not be taken for granted just because they are
natural.
Normally medicinal herbs contain potent, bioactive compounds. Many of
their pharmacological effects remain unidentified (Abas, 2001; Zakiah, 2001;
Barnes, 2003). In fact, their chemical constituents are far from being studied
thoroughly. This situation gets complicated when herbal preparations are mixed
with other known active ingredients (Erah, 2002) and when they are used as a
complement to conventional medicine. As known widely, the preparation and
formulation of herbal remedies is different to that of pharmaceutical synthetic
medicine. Even if they are now available in the forms of capsule, pills and oral
dosage forms but they are not scientifically prescribed by regulatory bodies and
the information on their efficacy, appropriate dosages and drug interactions are
poorly understood (Abas, 2001; Barnes, 2003). Therefore, they should be used
with caution and while they are relatively safe when taken properly as
preventive agents and for the promotion of health rather than strictly for healing.
8
Scientific evidence to justify their safety is much awaited (Abas, 2001; Mohsin,
2005).
Apart from the above, most of herbal preparation is not properly
standardised by scientific accredited methods. Standardisation of these
products is of particular importance to ensure their therapeutic efficacy (Azizol
and Rasadah, 2000). Most of the herbal products available in Malaysia are not
assessed for purity and consistency of active compound and this led to
misidentification, substitution and adulteration. These could be due to the
addition of incorrect species, altered mixtures of species, intentional or
unintentional inclusion of allergens, pollen, insect parts, heavy metals such as
lead, mercury and arsenic (Seeff, 2009) and scheduled poisons (drugs) (Abas,
2001). Therefore, a proper approach that allows highly precise standardisation
both chemically and biologically need to be put forward (Hylands, 2001).
Meanwhile, detailed toxicity and safety assessments of medicinal products and
subsequently the clinical trial must be performed to assure their safety and
efficacy for human consumption.
As the years go by, concern and awareness of any hazardous effects
derived from the utilization of herbs among consumers and clinical practitioners
are rising. This is a positive scenario where it will encourage the production of
safer and high quality herbal products. As emphasized in the WHO guidelines,
herbal medicine should be required to undergo toxicology testing in order to
verify their safety when used on the human (World Health Organization, 1998).
Since 1992, Malaysia through its Drug Control Authority (DCA) acting via its
9
secretariat, the NPCB has implemented regulatory measures to ensure the
quality and safety of any traditional products sent to them for approval and
registration. The registered products falling into the list of items under this
regulation are expected to be prepared in a scientific manner and comply with
the Good Manufacturing Practice (GMP) requirements. Nonetheless, such
products are only labelled as cures for general illness and not for treatment of
specific disease due to the lack of scientific data to support the claims of their
efficacy (Zakiah, 1999).
The dearth of detailed scientific information on the safety and efficacy of
herbal products are one of the major problem faced in our country. Indeed,
knowledge of their pharmacological properties and chemical constituents are
very limited in the literature. The pace of scientific advancement shows an
imbalance with the trend of herbal use. Hypothesis, assumptions and claims are
definitely not good enough for these products to gain support and acceptance
amongst professionals. The importance of the need for scientific research to be
carried out by trained scientists is a fact that cannot be denied. The application
of science and technology is vital indeed in the mission of transforming
ambiguous traditional preparations into modern authenticated pharmaceutical
products. Furthermore, systematic documentation and scientific explanation for
their properties as medicinals, are urgently needed and are of the utmost
importance in order to provide us with valuable and appropriate references on
local herbs.
10
1.3.2 Labisia pumila (Blume) Fern.-Vill
One of the most popular herbs that is receiving high demand by the local
populace in Malaysia is Labisia pumila or locally known as Kacip Fatimah (KF).
The term KF is used to describe the plant L. pumila in general. There are at
least four known varieties of L. pumila found in Malaysia (Stone, 1988; Mohd
Noh et aI., 2002). Though, only three of them are popularly used by the Malays
and these are L. pumila var. pumila (LPP), L. pumila var. a/ata (LPA) and L.
pumila var. lanceolata (LPL) (Stone, 1988).
If Tongkat Ali (Eurycoma 10 ngifolia) is supposed to benefit the male
species, L. pumila is closely associated to women and therefore thought to
benefit the female. It has been utilized by the Malays and aboriginal women of
reproductive age for numerous purposes. These include the balancing of bodily
function, promotion of women's health and as a sexual stimulant. According to
elderly Malays, this herb is a compulsory ingredient in most of the traditional
herbal preparation since it is believed that L. pumila could improve the
effectiveness of the other herbal products (Zainon, 2004). Traditionally, water
decoctions of the root or whole plant have been given to pregnant woman prior
to childbirth for the main purpose of inducing and facilitating labour (Stone,
1988; Jamia et aI., 1999a; Jaganath and Ng, 2000). It is also used as a
postpartum medication (Stone, 1988) in the form of mixed preparation to help in
the recovery of the post-gravid uterus. It is thought that the herb could
normalise the size and function of this organ in a shorter period than the
average of six weeks seen in normal mothers (Muhamad and Mustafa, 1994;
Yoga, 2003). Further, L. pumila is reported to extend fertility, to regularize blood
11
circulation and to help regain body strength of postpartum mothers (Muhamad
and Mustafa, 1994). Its other folkloric uses include treatment of dysentery,
flatulence, dysmenorrhoea, gonorrhoea, rheumatism, haemorrhoid and help to
firm and tone the abdominal muscles (Jamia et a/., 1999b; Jaganath and Ng,
2000). Other than that, many believe that this herb is able to enhance libido
(Asiah et aI., 2007), alleviate fatigue and promote emotional well being. Thus, it
is always recommended to women who have less interest in sex. Furthermore,
it is also claimed as a phytoestrogen and therefore may assist women in
achieving fuller breasts and can tighten vaginal muscles (Yoga, 2003; Ayida et
al., 2006).
The popularity of L. pumila is manifested by the emergence of many
commercial products in the Malaysian market. These come in many forms
including capsules, tablets, canned drinks and instant tea or coffee containing
this herb. These products are claimed to contain the ground or extracted parts
of the plant (Houghton et al., 1999; Wan Nazaimoon, 2002). Moreover, these
products are widely advertised by various advertising media. In fact, the
popularity of L. pumila is not only amongst Malays but other races as well.
Nevertheless up to the year 2002, there were no standardised preparation or
scientific data authenticating or evaluating the quality, safety and efficacy of this
herb (Houghton et al., 1999). In addition, little is known of the chemical
constituents of this plant.
Recognizing the importance and commercial potential of L. pumila as a
high quality herbal product or nutraceutical, the Government of Malaysia had
12
identified this herb as one of the priority species for a multi-disciplinary scientific
research. The research started in 2002, as part of the National Natural Product
Biotechnology Programme and funded by the National Biotechnology
Directorate under the Ministry of Science, Technology and Innovation (MOSTI).
Funding allocations are from the Ministry's Intensive Research on Priority Areas
of the eighth Malaysian Development Plan. Several universities and research
institutions, i.e. Institute for Medical Research (IMR), Forest Research Institute
of Malaysia (FRIM), Universiti Sains Malaysia (USM), Universiti Kebangsaan
Malaysia (UKM), Universiti Malaysia Sabah (UMS) and so forth are involved in
this research. The groups' objectives are summarised into five main efforts:
i) Sourcing and propagation of L. pumila - FRIM, UMS
ii) Standardisation of crude and formulated L. pumila - UKM
iii) Estrogenic and androgenic activities of L. pumila - IMR, HUKM
iv) General and reproductive toxicology of L. pumila - IMR, USM
v) Clinical trials (phase 1,2, 3) on L. pumila - IMR, HUSM, HUKM,
MOH, UH, HKL,
Ipoh Hospital.
(Wan Nazaimoon, 2002; IMR, 2003)
The present study is the effort of the fourth group above and is intended
to complement the overall documentation of L. pumila.
13
1.4 Scope of the study
The present study was designed to assess the possible reproductive,
developmental and female toxicities of LPA using animal model. The LPA
chosen is the most commonly used by the Malay community in the country
(Jamia et al., 2004) and can be easily obtained throughout the region. The type
and method of extract preparation as well as the route of administration in this
study were applied based on the traditional ways. This is to mimic the human
practices as close as possible and to induce similar effects in the animal model.
The decision to undertake this study is due to the fact that this herb is popular
and has been used as a natural remedy for female reproductive problems.
Couple to the above information, the lack of data on its safety make the
intention of this study all the more important.
A set of study comprising of a preliminary experiment and four main
studies were conducted in rats, as the best animal model for this study. Prior to
the commencement of the main study, a preliminary evaluation of teratogenicity
was conducted using self-prepared, unstandardised aqueous extract of LPA.
The main studies were subsequently performed as described below using
commercially prepared standard aqueous extract of LPA, registered with the
National Pharmaceutical Control Bureau (NPCB) as the trade name of
Biolabisia®. The studies are listed as follows:
(a) "Evaluation of the Teratogenicity of Biolabisia® in Rats" (hereinafter
referred as "Teratogenic study"). This study was designed to screen the
teratogenic potential of the herb when it is administered during the
organogenesis period.
14
(b) "Evaluation of the Female Reproductive Toxicity of Biolabisia® in Rats"
(hereinafter referred as "Reproductive toxicity study"). This study was
designed to screen the effects of the herb on reproductive function and
to mimic the traditional consumption of L. pumila during the reproductive
period, at the end of pregnancy (Stone, 1988; Jaganath and Ng, 2000)
and during confinement and breastfeeding (Stone, 1988).
(c) "Evaluation on the Effects of Biolabisia® on Fertility and Implantation in
Rats" (hereinafter referred as "Fertility study"). The design of this study
was to evaluate the effects of the herb on initiation of pregnancy and to
make a representation of the period where usage of L. pumila in human
continued into the early pregnancy period while the pregnant mother is
not aware of the pregnancy.
(d) "Evaluation of the Female Toxicity of Biolabisia® in Rats" (hereinafter
referred as "Female toxicity study"). This study was designed to
evaluate the effects of the herb during non-pregnancy state and to
reflect on conditions where L. pumila is consumed by women during the
peri menopausal period and in between pregnancies for energy gain
and for the sustenance of their reproductive health.
The results obtained from these experiments are expected to provide
useful information on the type and degree of toxicities of L. pumila on
reproductive system in rodent. The collection of data in this study is meant to
provide some basis for the development of the safety profile of this herb and
thereby help to alleviate concerns over its possible toxicity. Further, studies
using a second animal species, preferably non-rodent like rabbits for evaluation
15
of teratogenicity (ICH-S5A, 1994; OECD, 2001; Janer et al., 2008) and
monkeys for female toxicity study (Chahoud, 2004), need to be undertaken in
order to complete the investigation of reproductive toxicity of L. pumila in animal
models.
1.4.1 Test procedures and guidelines used
The designs and methods used in performing the female reproductive
and developmental toxicity studies as described in this thesis were adapted
from current internationally accepted guidelines (OECD, 1983; ICH Steering
Committee, 1993; WHO Regional Office for the Western Pacific, 1993; Manson
and Kang, 1994a; U.S. Food and Drug Administration, 2000b; U.S. Food and
Drug Administration, 2000a; Christian, 2001 c; OECD, 2001). These guidelines
were efforts of the World Health Organization (WHO), Organization for
Economic and Co-operation and Development (OECD), United States Food and
Drug Administration (U.S FDA) and International Conference on Harmonization
(ICH). Basically, all organizations address a similar standard guideline. Even
though each guideline is presented in its own way and approaches, all aspects
of reproductive and developmental toxicity testing are covered. These include
various study designs and evaluation endpoints as summarized within the
guidelines. Information of each organization and regulatory guidelines will be
elaborated in Chapter Two (subchapter 2.5) of the current thesis.
16
1.5 Objectives
1.5.1 General objectives
The general objectives of the present study were to evaluate the
potential effects of Biolabisia® on female reproductive system and development
of progenies in rats. This study is a part of the ultimate goal in an effort towards
establishing reliable safety profiles for the herb using animal model (rodent).
1.5.2 Specific objectives
The specific objectives of this study are listed below:
I. To prepare the aqueous extract of LPA and to determine
the appropriate dose range required for the elucidation of
the potential toxicity of the extract on female reproductive
system in rats through a preliminary study.
ii. To evaluate the teratogenic potential of commercially
prepared LPA (Biolabisia®) in pregnant rats by means of
the Teratogenic study.
iii. To evaluate the effects of Biolabisia® on reproductive
toxicity of pregnant rats via the Reproductive toxicity study.
iv. To assess the effects of Biolabisia® on fertility and
progression of implantation in pregnant rats by means of
the Fertility study.
v. To assess the potential female toxicity of Biolabisia® in non
pregnant rats via the Female toxicity study.
The research strategy of this study is indicated in Figure 1.1.
17
Discussion with the supervisor and research team on research activities.
Preparation of aqueous extract of LPA for the preliminary study.
l Preliminary study on the effects of aqueous extract of LPA on teratogenicity in rats.
1 1 1
Screening studies: Definitive studies:
1. Evaluation of the 3. Evaluation of the effects
teratogenicity of of Biolabisia® on fertility
Biolabisia® in rats. and implantation in rats.
2. Evaluation of the female 4. Evaluation of the female
reproductive toxicity of toxicity of Biolabisia® in
Biolabisia® in rats. rats.
Figure 1.1 Flowchart of the study indicating important research activities
18
1.6 Importance of the study
The evolution of scientific methodologies in herbal research uncovers
huge potential of developing medicinal herbs into therapeutic agents and other
health related chemical entities. Concurrently, the present research step up
emphasizes quality and safety issues of Biolabisia® that are paramount in
ensuring its safety. This research is expected to help establish relevant safety
profile and provide assessment of the potential toxicities of this herb during its
development as a herbal medicinal product.
Data regarding the adverse effects of L. pumila in human has not been
reported while no scientific work was ever attempted to investigate the
toxicology of this popular herb in the female reproductive system. The limited
scientific literature pertaining to its quality, safety and efficacy enhance the
urgency of conducting this present research. Information gathered could be
utilized as an initial scientific platform for the scientific community in particular,
as well as for the general public in general. Further, this research can be a
basis for the initiation of other related works investigating the potential
toxicological effects of other herbal preparations on female reproductive system.
This is especially pertinent for the Malaysian scenario.
Apart from expanding new knowledge regarding this herb, the present
research can also indirectly enlighten consumers about L. pumila and help to
alleviate fear or apprehension in using Biolabisia® as an alternative to the
synthetically produced pharmaceutical drugs. This is particularly so in relation to
the promotion of women's health. The confidence and support from the public
19
and professionals can inspire greater awareness and therefore help to improve
the herbal market on one hand while creating a stronger public demand for safe
products. This can also be a driving force for the development of newer safer
herbal medicines from the relatively rich, unexplored plant resources of
Malaysia.
Alternatively, the science of reproductive and developmental toxicology
applied in this study can also help in ensuring better understanding among
Malaysian researchers, while the need to establish adequate number of
expertise in this field is also becoming more urgent in Malaysia. In essence, the
development of new knowledge concerning potential hazards of consumer
products like herbal preparation will ultimately help protect the well-being of the
public via improved public health delivery.
20
CHAPTER TWO
LITERATURE REVIEW
2.1 Medicinal plants in Malaysia
The home to the world's richest biodiversity is widely recognized as
being located in the tropical regions (Bodeker, 2000). Nearly 35,000 to 70,000
species out of the estimated 422,000 flowering plant species in the world are
used for medicinal purposes. Out of this, at least 6,500 plant species had been
reported to have therapeutic properties are found in Asia. This makes Asia as
one of the largest biodiversity region of the world. Six of the world's 18
megabiodiversity hot spots are situated in Asia. These include the Eastern
Himalaya, North Borneo, Peninsular Malaysia, Sri Lanka, Philippines and the
Western Ghats of South India. All these areas are known as the concentrated
area of flora species richness (Handa, 2005).
Malaysia is blessed with exceedingly rich and diverse bioresources
potentials. In fact, the Malaysian tropical rain forest that evolved over 100
million years is one of the oldest and complex biological ecosystems in the
globe (Suhaimi et 81., 2001). These natural assets feed various industries and
have become the provider of natural resources chemical entities and biomass
for herbal, pharmaceutical, nutraceutical, pure phytochemical, cosmeceutical,
agrochemical industries et cetera.
21
A figure by EarthTrends Country Profiles (2003) indicated that a total
number of known higher plants in Malaysia from year 1992 to 2002 is 15,500
species. Bidin and Latiff (1995) and Parris and Latiff (1997) reported that the
flora of Malaysia is estimated to number around 15,000 species of flowering
plants and more than 1,170 species of ferns and fern allies. Peninsular
Malaysia alone is host to approximately 7539 species from 1510 genera of
flowering plants, 632 of ferns and fern-allies species and 27 of gymnosperms
species (Bidin and Latiff, 1995; Turner, 1995). Of these, about 1,200 species or
8% of the total flora has been used in various traditional medicinal practices
(Soepadmo, 1999). However, these numbers do not include the species found
in East Malaysia, which is believed to have some unique species only found in
that region. Sadly there is no known published exhaustive checklist of the
medicinal plants found in Sabah and Sarawak (Soepadmo, 1999; Kamarudin
and Latiff, 2002).
Since the past decades, the rural communities in Malaysia have been
proud of the role and contribution of medicinal plants as a source of their
traditional care systems, sustenance as well as in the production of herbal
medicinal products. It is estimated that 17.1% and 29.6% of Malaysian utilised
medicinal plants to treat their health problems and for health maintenance
respectively (Azriani et al., 2008a). Various groups such as Malay, Chinese,
Indian, the aborigines (Orang Asli) and other ethnic groups of Sabah and
Sarawak (Kadazan, Dusun, Iban, Bajau and so forth) have been identified as
the major consumers of medicinal plants (Mohd Azmi and Norini, 2001). Plant
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parts used for remedies include the roots, leaves, barks, seeds, flowers and
fruits (Haliza, 1994; Mohd Azmi and Norini, 2001).
The indigenous knowledge on medicine is mainly obtained through
heritage where the information is being passed over from generation to the next
generation (Halijah et al., 2005) through verbal or practices. Sometimes, the
knowledge is acquired from the traditional healers through special asceticism
(Haliza, 2000). However, the spread of information was slow and private among
small groups of people, which makes it difficult until now to find any manuscript
written by these traditional practitioners regarding the utilization of medicinal
plants. The Malay traditional healers are more comfortable to claim that their
knowledge are exclusive for their use or to be past down to members of their
family only (Mohsin, 2006). However, there is one Malay historical manuscript
namely the "Tajul Muluk" which describes ingredients of Malay traditional
medicine used by the ancient kings. But there is no thorough scientific
investigation of its contents nor any academic discourse as to how far it had
been referred to by other traditional practitioners in this country (Siti Amrah,
2004).
According to Kamarudin and Latiff (2002), for more than 50 years, the
books by Burkill and associates such as the "Malay Village Medicine" by Burkill
and Haniff (year 1930) and "A Dictionary of the Economic Products of the Malay
Peninsula" by Burkill (year 1935) were the only published reference available on
Malaysian medicinal plants in this region. Since then, not much studies or new
data collection were carried out. However, in the mid-1970s there has been a
23
resurgence of interest amongst young academics and researchers at the UKM,
Universiti Malaya (UM) and local research institutions on medicinal plants.
Realizing the importance of scientific research in this field, a multidiscipline
research team namely "Kumpulan Penyelidikan Ubatan Tradisional" or
"KUBATRA" in short, was subsequently set up in UKM in the early 1980s
(Kamarudin and Latiff, 2002).
KUBATRA has inspired the formation of other research groups, which
consisted of researchers and scientists from other universities. In 1985,
"Kumpulan Penyelidik Sebatian Semulajadi Malaysia" was set up and
subsequently developed into an established formal team namely "Persatuan
Sebatian Semulajadi Malaysia" in 1997. This organization spearheaded and
coordinated many annual research activities related to medicinal plants with
multidisciplinary approaches towards utilization, conservation and development
of safe, efficacious and quality products derived from medicinal plants. The
research activities included seminar, workshop, conference, forum and
publication that involved local and international researchers, academicians,
government, private sector, entrepreneurs and policy makers (Siti Amrah,
2004).
Presently, the government has taken many steps to encourage advance
scientific research, standardisation and introduction of new technology in the
quality control procedures related to medicinal plants. These efforts were
promoted while not ignoring aspects of conservation, good methodology,
cultivation and legislation relevant to the development of the herbal and
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